Are we there yet? Manifold identification of gradient-related proximal methods

Yifan Sun; Halyun Jeong; Julie Nutini; Mark Schmidt

Are we there yet? Manifold identification of gradient-related proximal methods

Yifan Sun
, Halyun Jeong
, Julie Nutini
, Mark Schmidt

Computer Science

University of British Columbia

Research output: Contribution to conference › Paper › peer-review

14 Scopus citations

Abstract

In machine learning, models that generalize better often generate outputs that lie on a low-dimensional manifold. Recently, several works have separately shown finite-time manifold identification by some proximal methods. In this work we provide a unified view by giving a simple condition under which any proximal method using a constant step size can achieve finite-iteration manifold detection. For several key methods (FISTA, DRS, ADMM, SVRG, SAGA, and RDA) we give an iteration bound, characterized in terms of their variable convergence rate and a problem-dependent constant that indicates problem degeneracy. For popular models, this constant is related to certain data assumptions, which gives intuition as to when lower active set complexity may be expected in practice.

Original language	English
State	Published - 2019
Event	22nd International Conference on Artificial Intelligence and Statistics, AISTATS 2019 - Naha, Japan Duration: Apr 16 2019 → Apr 18 2019

Conference

Conference	22nd International Conference on Artificial Intelligence and Statistics, AISTATS 2019
Country/Territory	Japan
City	Naha
Period	04/16/19 → 04/18/19

Cite this

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title = "Are we there yet? Manifold identification of gradient-related proximal methods",

abstract = "In machine learning, models that generalize better often generate outputs that lie on a low-dimensional manifold. Recently, several works have separately shown finite-time manifold identification by some proximal methods. In this work we provide a unified view by giving a simple condition under which any proximal method using a constant step size can achieve finite-iteration manifold detection. For several key methods (FISTA, DRS, ADMM, SVRG, SAGA, and RDA) we give an iteration bound, characterized in terms of their variable convergence rate and a problem-dependent constant that indicates problem degeneracy. For popular models, this constant is related to certain data assumptions, which gives intuition as to when lower active set complexity may be expected in practice.",

author = "Yifan Sun and Halyun Jeong and Julie Nutini and Mark Schmidt",

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TY - CONF

T1 - Are we there yet? Manifold identification of gradient-related proximal methods

AU - Sun, Yifan

AU - Jeong, Halyun

AU - Nutini, Julie

AU - Schmidt, Mark

PY - 2019

Y1 - 2019

N2 - In machine learning, models that generalize better often generate outputs that lie on a low-dimensional manifold. Recently, several works have separately shown finite-time manifold identification by some proximal methods. In this work we provide a unified view by giving a simple condition under which any proximal method using a constant step size can achieve finite-iteration manifold detection. For several key methods (FISTA, DRS, ADMM, SVRG, SAGA, and RDA) we give an iteration bound, characterized in terms of their variable convergence rate and a problem-dependent constant that indicates problem degeneracy. For popular models, this constant is related to certain data assumptions, which gives intuition as to when lower active set complexity may be expected in practice.

AB - In machine learning, models that generalize better often generate outputs that lie on a low-dimensional manifold. Recently, several works have separately shown finite-time manifold identification by some proximal methods. In this work we provide a unified view by giving a simple condition under which any proximal method using a constant step size can achieve finite-iteration manifold detection. For several key methods (FISTA, DRS, ADMM, SVRG, SAGA, and RDA) we give an iteration bound, characterized in terms of their variable convergence rate and a problem-dependent constant that indicates problem degeneracy. For popular models, this constant is related to certain data assumptions, which gives intuition as to when lower active set complexity may be expected in practice.

UR - https://www.scopus.com/pages/publications/85085017105

M3 - Paper

AN - SCOPUS:85085017105

T2 - 22nd International Conference on Artificial Intelligence and Statistics, AISTATS 2019

Y2 - 16 April 2019 through 18 April 2019

ER -

Are we there yet? Manifold identification of gradient-related proximal methods

Abstract

Conference

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